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Josia Pietsch 2024-02-10 05:20:35 +01:00
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inputs/lecture_02.tex
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@ -91,7 +91,6 @@
because $\tilde{f_U}$ is continuous. because $\tilde{f_U}$ is continuous.
It is closed}{} in $X \times \R$ \gist{because It is closed}{} in $X \times \R$ \gist{because
$\tilde{f_U} \to \infty$ for $d(x, U^c) \to 0$}{}. $\tilde{f_U} \to \infty$ for $d(x, U^c) \to 0$}{}.
\todo{Make this precise}
Therefore we identified $U$ with a closed subspace of Therefore we identified $U$ with a closed subspace of
the Polish space $(X \times \R, d_1)$. the Polish space $(X \times \R, d_1)$.

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inputs/lecture_11.tex
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@ -96,7 +96,7 @@
Polish space and $\cC = 2^\omega$ the Cantor space, Polish space and $\cC = 2^\omega$ the Cantor space,
then they are Borel isomorphic. then they are Borel isomorphic.
There is $2^\omega \hookrightarrow X$ Borel There is $2^\omega \hookrightarrow X$ Borel
(continuous wrt.~to the topology of $X$) (continuous wrt.~the topology of $X$)
On the other hand On the other hand
\[ \[
X \hookrightarrow\cN \overset{\text{continuous embedding\footnotemark}}{\hookrightarrow}\cC X \hookrightarrow\cN \overset{\text{continuous embedding\footnotemark}}{\hookrightarrow}\cC

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inputs/tutorial_05.tex
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@ -119,5 +119,3 @@
Then $f(B) = U_{(x_0,\ldots,x_{n-1})}$ is open, Then $f(B) = U_{(x_0,\ldots,x_{n-1})}$ is open,
hence $f$ is open. hence $f$ is open.
\end{enumerate} \end{enumerate}

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inputs/tutorial_08.tex
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@ -95,7 +95,7 @@ for some $B_i \in \cB(Y_i)$.
Then $\bigcap A_i$ is the image of $D$ Then $\bigcap A_i$ is the image of $D$
under $Z \xrightarrow{(y_n) \mapsto f_0(y_0)} X$. under $Z \xrightarrow{(y_n) \mapsto f_0(y_0)} X$.
\paragraph{Other solution} \emph{Other solution:}
Let $F_n \subseteq X \times \cN$ be closed, Let $F_n \subseteq X \times \cN$ be closed,
and $C \subseteq X \times \cN^{\N}$ defined by and $C \subseteq X \times \cN^{\N}$ defined by